RU2488848C1 - Method of exciting seismic waves - Google Patents

Abstract

FIELD: physics.

SUBSTANCE: disclosed is a method of exciting seismic waves using an energy converter, having an active part and a reactive part, a drive for cyclic movement of the reactive part and a system for controlling movement of the reactive part. According to the disclosed solution, kinetic energy reserves of the reactive part are created and force action of the active part is applied onto the investigated medium by transferring energy from the reactive part to the active part. Independence of cyclic movement of the reactive part from the active part is structurally provided and the force action of the active part is applied on the investigated medium independent of the cyclic nature of movement of the reactive part.

EFFECT: high seismic efficiency.

1 dwg

Description

The invention relates to methods for exciting seismic waves in seismic exploration based on the use of kinetic energy of moving masses.

There is a known method of exciting seismic waves, based on the electromagnetic acceleration of a falling load made of magnetic material and moving along the guide rails inside the column of non-magnetic material, and after freeing for free fall, the load is accelerated by electromagnets located along the column and automatically returns to the top position after hitting the ground (US patent No. 3302744, N. cl. 181-05, publ. 1967).

The disadvantages of this method are the loss of energy and time to move the load, the low frequency of repetition of force effects on the medium under study and the inability to control the spectrum of excited seismic waves.

There is also known a method of exciting seismic waves using an electromechanical transducer, including installing a support device on the ground, creating a supply of energy in the load when it rises and falls, generating and applying an electrical impulse to the electromagnet coils of the support device and transmitting a force to the soil through the support device, this carry out the dumping of the load at the time of the start command, and its braking - after a specified period of time after the start command (author’s USSR Government No. 958999, IPC G01V 1/147, publ. 1982).

The disadvantages of the known method of exciting seismic waves are the loss of energy and time to move the load, the low frequency of repetition of force on the medium under study and the inability to control the spectrum of excited seismic waves.

The closest technical solution, selected as a prototype, is a method for exciting seismic waves using an electromechanical transducer containing the active and reactive parts and a winding for controlling the movement of the reactive part, including the creation of a reserve of kinetic energy in the reactive part of the converter and the force action of the active part on the medium under study at applying an electrical impulse to the winding of motion control of the reactive part, while the active and reactive parts transform the driver is installed with the possibility of rotation of one relative to the other and kinetic energy is stored by bringing the reactive part of the converter into rotation (RF patent No. 20188880, IPC G01V 1/02, publ. 1994).

The disadvantages of the known method of exciting seismic waves are the unsatisfactory energy and seismic efficiency of the excitation of seismic waves, due to the significant duration of the pulses of force on the medium under study and, accordingly, their low repetition rate, as well as the inability to control the spectrum of excited seismic waves. The root cause of the disadvantages of the known method of exciting seismic waves is the inertia of the electromechanical transducer, which is the result of installing its active and reactive parts on a common axis with the possibility of rotation of one relative to the other.

The objective of the present invention is to increase the energy and seismic efficiency of the excitation of seismic waves.

The problem is solved in that in the method of exciting seismic waves using an energy converter containing the active and reactive parts, a drive for cyclic movement of the reactive part and a control system for the movement of the reactive part, including the creation of a reserve of kinetic energy of the reactive part and the implementation of the force acting on the active medium under study by transferring energy from the reactive part to the active part, according to the invention structurally provide independence of the cyclic motion pressure of the reactive part relative to the active part and perform control of the force action of the active part on the medium under study, independent of the cyclical movement of the reactive part.

Compared with the prototype, the proposed method for exciting seismic waves has the following differences:

- uses the types of energy and the corresponding energy converters that best meet the technical and technological requirements of a particular implementation of the method; the prototype uses electrical energy and, accordingly, an electromechanical energy converter;

- uses the cyclic movement of the reactive part and the corresponding drive; the prototype uses rotational motion and, accordingly, a rotary drive;

- the active and reactive parts of the energy Converter are structurally made with the possibility of mechanical independence of movement; in the prototype, the dependence of the movement of the active and reactive parts of the converter is due to their installation on a common axis of rotation;

- the control system for the movement of the reactive part, regardless of the cyclical movement of the latter, modulates the energy flow from the reactive to the active part in accordance with a given law of changing the magnitude and form of the force acting on the medium under study; in the prototype, the ability to control the parameters of the pulsed force action on the medium under study is limited by the significant pulse duration and low frequency of their repetition, commensurate with the cyclical nature of the drive.

Existing seismic vibrators in the power unit are hydromechanical converters of the energy of the fluid flow into the energy of seismic waves. Electromechanical impulse seismic sources are also used in seismic exploration. The implementation of the method of exciting seismic waves according to the invention is possible using electromechanical or hydromechanical energy converters, as well as by expediently combining the types of energy and corresponding converters.

The implementation of the method of excitation of seismic waves according to the invention is possible using rotary or vibrational drives and, accordingly, rotational, vibrational or combined rotational-vibrational energy converters, the reactive parts of which act as storage of kinetic energy and reduce internal energy losses and sound and seismic noise caused by primary engines of sources of excitation of seismic waves.

The structurally mechanically independent movement of the active and reactive parts of the energy converter provides for a decrease in the inertia of its operation and an increase in the efficiency of controlling the spectrum of excited seismic waves.

Structurally, the independence of the formation of excited oscillations from the cyclic action of the energy transducer and the completeness of the useful use of the excitation time are ensured by sectioning the transducer and correspondingly matching the combined operation time of its sections, which allows for short, continuous pulsed bursts of oscillations within the cycle, or long, lasting for many cycles vibrations modulated in accordance with a given form of force impact on the study when the wind blows on Wednesday.

An electromechanical oscillatory device for implementing the proposed method for exciting longitudinal seismic waves is shown in the drawing, which uses the following notation: 1 — the active part of the electromechanical converter, 2 — the reactive part of the electromechanical converter, 3 — the elastic suspension of the reactive part, 4 — the windings for controlling the movement of the reactive part, 5 - magnets or electromagnets, 6 - drive of the reactive part, 7 - shell, 8 - bearing rod, 9 - radiating plate, 10 - load, 11 - springs, 12 - electric block anija actuator 13 - switching unit and motion control power windings reactive part and energy recovery, 14 - the device control unit.

A device for implementing the method of exciting seismic waves consists of two structurally identical sections, differing modes of coordinated functioning in the process of excitation of seismic waves. Each of the sections consists of the active part 1 mounted on the carrier rod 8 of the device with the reactive movement control windings 4 mounted on it and the reactive part 2 suspended on the elastic suspension 3 to the shell 7 with the magnets (or electromagnets) 5 mounted on it and the drive elements 6 reactive parts, some of which are mounted on the shell 7. The common structural elements of the partitioned device are the supporting rod 8, the radiating plate 9, the load 10, the springs 11, the power supply unit 12 of the actuators 6 reactive parts Tei 2, the switching unit 13 and power windings 4 reactive motion control parts 2 and energy recovery control unit 14.

In mobile devices, the weight of the vehicle is used as a load 10. In this case, the springs 11 serve to mechanically decouple and protect the vehicle from vibrations of the radiating plate 9. To prevent the oscillating radiating plate 9 from tearing off the ground, the static force of its clamp created by the load 10 must exceed the maximum working amplitude of the vibration force of the device. To carry out tripping operations in transported devices, part of the internal volume of the shell 7 is reserved for moving the active part 1, and holes are made in the upper and lower floors of the shell for placing and moving the carrier rod 8.

As the drive 6 of the reactive parts of the 2 sections, linear motors formed by permanent magnets or electromagnets mounted on the more mobile reactive parts of the sections and windings installed on the less mobile shells of 7 sections mounted on the load 10 can be used.

The active part 1 of the section with windings 4 and the reactive part 2 of the section with magnets (or electromagnets) 5 form an electromechanical converter of the section.

The reactive part 2 and the elastic suspension 3 of each section form a mechanical oscillating system, driven by the drive 6. The force action of the oscillating reactive part 2 on the active part 1 arises as a result of the electromagnetic interaction of the magnets 5 and the windings 4 when current flows in them.

The windings 4 and block 13 of their switching and power supply and energy recovery form a control system for the movement of the reactive parts 2 of the device and, in addition, are elements of the recovery of the kinetic energy of their vibrational motion.

The forces developed by the sections are summed up on the supporting rod 8, and the total force is transmitted to the emitting plate 9, by which it acts on the medium under study. In general, a partitioned device for implementing the method consists of a structurally common active part of the electromechanical converter of the device formed by the active parts of 1 sections, a supporting rod 8 and a radiating plate 9, and a functionally generalized reactive part of the electromechanical converter of the device formed by reactive parts 2 and elastic suspensions of 3 sections.

The independence of the mechanical movement of the generalized reactive part relative to the common active part is structurally ensured by the fact that the active parts of the sections 1 are rigidly connected to the supporting rod 8 and the radiating plate 9, and the reactive parts of the 2 sections are connected with the load 10 using elastic suspensions 3.

A device for implementing the method can be equipped with sensors for monitoring mechanical and electrical quantities (not shown) mounted on fixed and movable elements of its structure. The output signals of the sensors on lines 4-14 and 6-14 or similar communications are received in the control unit 14 and are used to optimize the operation of the device.

The method of exciting seismic waves according to the invention is as follows.

A device for implementing the method is installed at a given point on the earth's surface and transferred from the transport to the working position. In this case, the radiating plate 9 is pressed through the springs 11 to the soil with a weight of 10, and the windings 4 and magnets 5 are installed in the position of the effective electromagnetic interaction controlled by the corresponding sensor.

In the process of excitation and registration of seismic waves, the communication device for implementing the method with seismic recording equipment is made through the control unit 14. Previously, on the start command of the device, produced on line 14-12, using actuators 6, powered from block 12 on line 12-6, reactive Part 2 of the electromechanical transducer is driven into oscillatory motion. The establishment of a given working amplitude of the oscillations means the readiness of the device to excite waves. For the known parameters of the oscillatory system, the time for establishing the oscillations is known and can be counted by the chronometer or determined directly by the achievement of a given amplitude of oscillations controlled by the corresponding sensor.

At the command for the initiation of seismic wave excitation, the control unit 14, through line 14-13, modulates the energy flow from the reactive to the active part of the electromechanical transducer in accordance with a given law of changing the magnitude and shape of the force acting on the medium under study.

At an arbitrary point in time of each of the sections of the device, a force action can be made on the medium under study with a given direction of the force vector. If the direction of the velocity vector of the reactive part of the section coincides with the given direction of the vector, the forces acting on the medium are carried out by short circuiting in block 13 (for example, using thyristors) the windings 4 to the capacity of the energy recovery system. In this case, the movement of the reactive part of the section is slowed down, and the electromechanical converter operates in the mode of an electric generator with the recovery of recovered energy along line 4-13 to block 13. When the opposite direction of the velocity vector of the reactive part of the section and the specified direction of the vector of the force of influence on the medium is carried out by creating a counter-emf on windings 4, fed from block 13 along line 13-4. In this case, the movement of the reactive part of the section is accelerated, and the electromechanical converter operates in the mode of an electric motor - a consumer of recovered energy. In both cases, the magnetic field of the current generated in the windings 4 interacts with the field of magnets 5 and creates a force, on the one hand, slowing down or accelerating the movement of the reactive part 2, on the other hand, acting on the active part 1 and transmitted through the bearing rod 8 and the radiating plate 9 on the ground and the test environment.

For a two-section device, it is optimal to work with the same resonant frequency for both sections with a relative phase shift equal to a quarter of the period of the oscillation frequency. In this case, the maximum possible amplitude for the two-section device is achieved for the amplitude of the total force impact of the sections on the medium, provided that the parameters of the latter are independent of the cyclic action of the device. In the case of economic and constructive feasibility of increasing the number of sections, the efficiency of ensuring the independence of the force impact on the medium under study from the cyclic operation of the device is increased.

Additionally, the functional provision of independence of the excitation of seismic vibrations from the cyclic operation of the partitioned device consists in a certain correction of the section control signals supplied to the windings 4 for a given law of force action on the medium under study by appropriate programming of the operation of block 14.

The use of resonant oscillatory systems and the recovery of the mechanical energy of their movement allows creating energy-efficient devices powered by electric energy batteries for implementing the method and disabling primary engines-sources of mechanical energy during the excitation of useful seismic vibrations, which create significant sound and seismic noise.

Depending on the production or technological necessity, the device for implementing the method according to the invention can operate in the mode of excitation of pulsed, polyimpulse or vibrational signals. The choice of a particular mode is determined by setting the appropriate control signals.

Depending on the area of use and technological features of the method (ground, water, borehole seismic exploration, deep seismic studies) and devices for its implementation, electromechanical, hydromechanical or combined electro-hydromechanical energy converters are used, rotational, oscillatory or combined rotational-vibrational principle of their action, continuous or discrete formation of force impact on the environment.

The type of excited seismic waves (longitudinal or transverse) and the polarization of transverse waves (vertical or horizontal) are determined structurally by the corresponding spatial orientation of structural elements that exert a force on the medium under study.

The energy efficiency of the method and devices for its implementation is ensured by the use of economical oscillatory or rotational energy storage devices and energy recovery devices in their composition, as well as by the rational use of seismic energy by controlling the spectrum of excited oscillations and predominantly enriching frequencies that suffer increased losses in the medium and are complicated by intense noise .

The seismic efficiency of the method and devices for its implementation is provided by the possibility of exciting the most informative types of waves and controlling their polarization and spectral composition in order to achieve a given time and amplitude resolution of the studies.

Claims (1)

A method for exciting seismic waves using an energy converter containing the active and reactive parts, a drive for cyclic movement of the reactive part and a system for controlling the movement of the reactive part, which includes creating a reserve of kinetic energy of the reactive part and exerting a force on the medium under study by transferring energy from the reactive part to active part, characterized in that structurally ensure the independence of the cyclic movement of the reactive part relative to the act implicit part and runs independently of the cyclic movement of the reactive power control of the influence of the active part in the test medium.